1,5-Pentanediol (1,5-PDO) is a high-value chemical with broad uses in polymer, cosmetic, and pharmaceutical industries. Although diverse biosynthetic pathways have been constructed, current recombinant strains typically rely on plasmid-based overexpression, which necessitates antibiotics and hinders industrial-scale production. We developed a robust, plasmid-free Escherichia coli platform for de novo 1,5-PDO synthesis by integrating pathway genes (davB, davA, gabT, yahK, car, sfp and yqhD) into the chromosome of a lysine-hyperproducing strain via CRISPR/Cas9. Screening of carboxylic acid reductases identified Nocardia iowensis CAR-Ni as the most effective, yielding a base strain (D13) that produced 0.672 g/L 1,5-PDO. Integrated analysis confirmed the alcohol dehydrogenase (ADH)-mediated reduction of 5-hydroxypentanal (5-HP) as an underappreciated bottleneck. We subsequently screened ten endogenous ADHs and selected YjgB for computational optimization. Docking-guided saturation mutagenesis at position E205 yielded the variant YjgB(E205C), which exhibited a 3.34-fold increase in in vitro activity, reduced 5-HP accumulation, and elevated the titer to 0.935 g/L. Enhancing NADPH supply by integrating pntAB further raised the shake-flask titer to 1.5 g/L. In a 5-L fed-batch bioreactor, the final strain (D91) achieved 12.1 g/L 1,5-PDO (yield of 0.225 mol/mol glucose) without antibiotics or inducers. To our knowledge, this is the highest reported 1,5-PDO titer in E. coli. This study establishes a scalable, sustainable biosynthetic platform through synergistic metabolic engineering and computational enzyme optimization.
Deng et al. (Wed,) studied this question.